The uses of orthodontic study models in DIAGNOSIS AND TREATMENT PLANNING
1. THE USES OF ORTHODONTIC
STUDY MODELS IN DIAGNOSIS AND
TREATMENT PLANNING
2. INTRODUCTION
Orthodontic diagnostic records are taken to:
Document the starting point or patient’s initial
condition. supplement the information gathered
during clinical interview and examination. The
records can be divided into three categories: study
casts, photographs, and radiographs. These are
important medico-legal ‘documents’ that should be
obtained even for the simplest forms of procedures,
and form the basis for planning orthodontic
treatment.
3. This article attempts to introduce some of the uses
of study casts in the planning of orthodontic
treatment. For orthodontic diagnosis, we need to
ascertain the shape and size of the teeth; their
positions and the extent of crowding/spacing of
teeth within the jaw; their occlusal relationships
and the results of other special investigations.
INTRODUCTION
5. Failure to count the teeth is a common mistake
counting must include those that are visible as
well as those developing within or outside the
jaws (as revealed by radiographs). Congenital
absence of teeth should also be noted.
Tooth number
6. Tooth shape
Study casts provide a very clear view for the clinician to
assess dental crown morphology and anatomy. Tooth
anomalies can be classified as arising from: tooth formation,
eruption, and alignment. It is not unusual to find shovel-
shaped or peg-shaped incisors, dens evaginatus and
invaginatus, talon cusps, double teeth, Carabelli’s traits, and
other anomalies of dentition. These unusual morphologies will
affect dental occlusion as well as the tooth size discrepancy.
talon cusps peg-shaped incisors
7. Such unusual dental morphology can affect the
extraction choice during treatment planning. For
example, dens evaginatus commonly affects
premolar teeth of orientals. The reported prevalence
of dens evaginatus was 3% in 12-year-old Hong
Kong Chinese and 2.1% in 10-year-old
Singaporeans. Fracture or attrition of the tubercle of
dens evaginatus may result in an enamel defect
and/or exposure of the pulp; thus, pulpal
inflammation and necrosis may occur before or after
complete root formation.
Tooth shape
8. Tooth size and
spaceStudy casts are very useful in assessing the
relationship between the tooth size and the size of
supporting structures, which can be based on the
space analysis technique.
According to Kirschen, such space analysis can assist
clinicians in various aspects of diagnosis and
treatment planning. In principle the analysis depends
on comparing the space required for alignment of the
teeth and the actual space available.
9. The space analysis method suggested by Nance
was carried out by:
(1) Measuring the mesiodistal width of each tooth
mesial to the first permanent molar. The total sum of
the mesiodistal width corresponds to the space
required for the alignment of teeth .
(a) Measurement of tooth width.
10. (2) Measuring the actual arch length by contouring a soft wire
to the individual arch shape over the contact points of posterior
teeth and the incisal edges of the anteriors .The distance of the
straightened wire is the available space for the alignment of
teeth.
(b) Upper arch and (c) lower arch for measuring arch
length
11. Another method divides the dental arch into four
segments: from mesial aspect of the first permanent
molar to the distal aspect of the canine of the same
side; then to mesial of centrals: then to distal of
canine of the other side; then to mesial of first
permanent molar of the other side. Arch length can
be measured as straight line approximations of the
arch .
12. Space analysis in mixed
dentition
As the permanent teeth are not fully erupted during
the mixed dentition stage, estimation of the unerupted
permanent teeth is necessary for the mixed dentition
space analysis. The aim is to compare the space
available for the unerupted permanent canine and
premolars with the space needed, the difference is
then the amount of crowding, or of spacing, present.
The following is the method used in the Orthodontics
Department in the University of Hong Kong.
13. To measure the space available, mark the distance, in the
line of the arch, that is needed for the alignment of the
central and lateral incisors. This distance shows how much
of the arch perimeter will be taken up during alignment of
the mandibular incisors. If the teeth are well aligned, no
correction is needed. Repeat for both sides. Now measure
the space available for the unerupted canines and
premolars. This is the distance from the mesial of the first
permanent molar to the calculated ‘after alignment’ position
of the distal corner of the lateral incisor .
The estimated position of distal surface
of lateral incisor (with lower incisors
aligned) is marked on the lingual surface
of lower canine. This mark is used for
measurement of the space available for
permanent canine and premolars
14. Estimation of the size of the unerupted teeth can be carried out
using three basic approaches suggested by Proffit and
Ackerman namely: (1) measurement of the teeth on radiograph;
(2) estimation from proportionality tables; and (3) combining
data from radiographs and prediction tables. The radiographic
method requires an undistorted image in order to obtain
accurate estimations. Compensation for any enlargement of the
radiographic image involves measuring an object that can be
seen on the radiograph (apparent width) and on the study casts
(true width), using a simple proportional relationship setup.
Measurement of apparent widths of canine and premolars
15. True width of primary molar
Apparent width of primary molar
True width of unerupted premolar
Apparent width of unerupted premolar=
The accuracy of the method is fair to good, depending on the
quality of the radiographs and the position of the teeth in the
arch. It can be used for the upper and lower arch in all ethnic
groups, but obtaining an undistorted view of the canines is
usually difficult. The Moyers prediction table is one of the well-
known methods for predicting the size of unerupted teeth; the
lower incisors width measurements are used to estimate the
size of maxillary and mandibular unerupted canines and
premolars.
16. Tanaka and Johnston 12 developed an
alternative means based on the formula:
0.5 x
(Mesiodistal
width of four
lower
incisors)
+ x mm =
Estimated
mesiodistal
width of canine and
premolars per
quadrant
(where x=10.5 for the mandibular arch
and 11.0 for the maxillary archs)
17. The Moyers as well as the Tanaka and Johnston
predictions were both based on white children of
northern European descent. For Southern Chinese,
the Tanaka and Johnston method needs some
adjustments, due to tooth size difference between
ethnic groups as well as between the Southern
Chinese males and females . The authors
recommended that for males, the x value should be
10.5 for the mandibular arch and 11.5 for the
maxillary arch. Corresponding values for females
were 10.0 and 11.0, respectively.
18. The combination method entails measurements from
the study casts and width measurements from the
periapical radiograph, in order to further improve
prediction accuracy. The sizes of the permanent
incisors measured from the dental casts and that of
the unerupted premolar from the periapical X-rays are
used to predict the size of unerupted canines. Staley
and Kerber modified the Hixon and Oldfather method,
to develop a prediction graph using the Iowa growth
data, which allows canine width to be read off directly
from the graph.
19. This prediction graph provides the relationship
between the size of lower incisors measured from
study casts plus the first and second premolars
measured from radiographs (x-axis) and the size of
the canine plus premolars (y-axis). The Staley and
Kerber method was based on Caucasian children
of northern European descent. Moreover, this
method is only applicable to the mandibular arch.
20. To conclude, for Caucasian children, the Hixon and
Oldfather method gives the best prediction followed
by the methods described by Tanaka and Johnston
as well as by Moyers. The Tanaka and Johnston
approach is the most practical, since no radiographs
are required and for the Chinese, the modified
Tanaka and Johnston approach is the most
practical. For other ethnic groups, direct
measurement from the radiographs is the best
approach.
21. Tooth size
discrepancies
Comparing tooth size, available space and
identification of disharmonies of tooth size
within the dental arch has a great impact during
orthodontic diagnosis and treatment planning,
as space management is very important. For a
good occlusion, the dentition needs to be
proportionately sized.
22. The Bolton Analysis is named after its inventor and
is very frequently used in the field of orthodontics to
detect tooth size discrepancy. The analysis
determines the ratio of the mesiodistal widths of
maxillary versus mandibular teeth. It helps to
estimate the overbite and overjet relationship, that
will likely be obtained after orthodontic treatment is
complete and the occlusal misfits produced by
interarch tooth size discrepancy are identified .The
overall ratio determines the relationship between
the 12 mandibular and 12 maxillary teeth (after
excluding the second and third molars);.
23. the anterior ratio is between the six upper and lower
anteriors .The procedure is as follows: the sum of
the widths of the 12 mandibular teeth is divided by
the sum of the 12 maxillary teeth and multiplied by
100. A mean ratio of 91.3, according to Bolton, will
result in ideal overbite overjet relationships, as well
as posterior occlusion. If the overall ratio exceeds
91.3, the discrepancy is due to excessive
mandibular tooth material and vice versa.
24. A similar ratio (anterior ratio) is computed for the six
anterior teeth (incisors and cuspids). An anterior
ratio of 77.2 provides ideal overbite and overjet
relationships, so long as the angulation of the
incisors is correct and the labiolingual thickness of
the incisal edges is not excessive. If the overall
ratio exceeds 77.2, the discrepancy is due to
excessive mandibular tooth material and vice
versa.
25. A tooth size discrepancy of less than 1.5 mm is
relatively insignificant 1 but larger discrepancies
(e.g. > ±2 SD) create treatment problems. In a
Chinese sample, it was reported that the Bolton
standards applied to Southern Chinese children with
Class I occlusion, but not to those with Class II or
Class III occlusions for whom specific standards
need to be established.
26. Dental archform
Assessment of dental archform is an important
aspect of orthodontics because depending on
conditions, some archforms have to be altered while
others need preserving. The dental archform can be
defined as the position and relationship the teeth
have to each other .Felton et al reported that as
there is great individual variability in archform, in
many cases customizing the individual archform
appears necessary to obtain optimum long-term
stability.
27. According to de la Cruz et al , archform tended to
return toward the pretreatment shape after retention
and suggested that the patient’s pretreatment
archform be used as a guide for future archform
stability.
28. Asymmetry within the dental arch can result from lateral drift of
incisors or drift of posterior teeth. Lateral drift of incisors
occurs frequently in patients with severe crowding, particularly
if the primary canines are lost prematurely. Posterior drift is
usually caused by early loss of primary molar teeth
Grid to check archform and
symmetry
29. .The features of mesially drifted posterior teeth could
be:
(1) crowding and space loss;
(2) dental midline shift with crowding and space loss;
(3) mesial tipping of permanent molars; or
(4) rotation of permanent molars . A grid can be used
to check the symmetry and form of the dental arch .
Grid to check archform and
symmetry
30. The curve of Spee
The curve of Spee is defined as the anatomic curve established
by the occlusal alignment of the teeth, as projected onto the
median plane, beginning with the cusp tip of the mandibular
canine and following the buccal cusp tips of the premolar and
molar teeth .The curve of Spee is measured by determining the
furthest perpendicular distance from a line connecting the
second molar and the central incisor. The importance of this
curve in orthodontic planning is that it requires space to
become level without proclining the incisors .Thus, a 3-mm
deep curve of Spee requires 3 mm of space for leveling (1.5
mm for each lower quadrant) .
Space required for
leveling curve of
Spee
31. Measurement of the curve of spee
The depth of the curve of spee is defined as the distance from the
vertix of the curvature to the side of a plastic template placed over
the lower arch .the template touches anteriorly the incisal edges
and posteriorly the distal most molar cusps. The measurment is
carried out separately on both the left and right sides of the dental
arch.
35. Diagnostic
setupThe diagnostic setup helps clinicians ascertain the
precise amount of tooth movement and direction of
movement, before orthodontic treatment . By this
means, space problems in the permanent dentition
can be used to visualize in three dimensions, by
cutting off the teeth from a set of casts and resetting
them in more desirable positions.
Diagnostic setup
36. When extractions are contemplated as part of the
orthodontic treatment for tooth size discrepancies or
missing teeth, the diagnostic setup will vividly
demonstrate the amount of space created by the
extractions, and the tooth movements necessary to
close the space. It will also aid in choosing which
teeth to extract. It is also useful in multidisciplinary
cases where crown modification, extractions, or
prosthesis/implants are needed.
37. Based on the setup, the orthodontist will know how
much to move each individual tooth and the
restorative dentist will know to what extent the teeth
should be reshaped and how prostheses/implants
should be placed.
38. Howes’ Analysis
Howes’ Analysis was devised to help clinicians
determine whether apical bases could accommodate
patient’s teeth and in cases with suspected apical
bases deficiency decide whether to extract teeth, or
carry out dental or palatal expansions. Howes
believed that the premolar basal arch width should
equal approximately 44% of the mesiodistal widths of
the 12 teeth in the maxilla, if it was to be sufficient to
accommodate all the teeth.
39. When the ratio between basal arch width and tooth
material is less than 37%, Howes considered this to
be a basal arch deficiency, necessitating extraction
of premolars. If the premolar basal width was greater
than the premolar coronal arch width, expansion of
the premolars may be undertaken safely. Details of
the technique are summarized in Moyer’s standard
text.
40. The Royal London Space Planning
The Royal London Space Planning process has
evolved since 1985 to ensure a disciplined
approach to diagnosis and treatment planning and
to provide a record to justify treatment decisions for
professional accountability . The analysis takes into
consideration most aspects of a given malocclusion
and aims to quantify the space required in each
dental arch to attain the treatment objectives. This
space planning also helps determine whether the
objectives are likely to be attainable and helps in the
planning of treatment mechanics and the control of
anchorage.
41. The process of analysis is divided into two sections.
The first part entails assessing the original
malocclusion according to various components
(which includes crowding and spacing, occlusal
curves, arch width, anteroposterior position of labial
segments, mesiodistal angulation, and incisor
inclination). Any one of these can have an effect on
space, if altered during treatment. The second part
of the analysis, deals with the effect of treatment
procedures (extractions, tooth size modifications,
distal or mesial molar movements) as well as
natural growth on the space required. The entire
procedure has been comprehensively described in
the original literature .
42. To assess and record the jaw
relationshipThis three-dimensional (3D) analysis estimates the
intermaxillary relationship between the upper and
lower dental arches in anteroposterior, transverse,
and vertical dimensions. For the anteroposterior
relationship, the overjet (increased/reduced) and the
molar/canine relationships (e.g. angle classification)
can be assessed. For the anteroposterior
assessment, the molar relationship will affect the
decision as to whether the molars need distal or
mesial movement and the anchorage demand can
also be assessed.
43. The transverse analysis using the midsagittal plane as
the reference, can be used to evaluate maxillary and
mandibular midlines coincidence, transverse
symmetry of the arches and interarch transverse
relationships which can be normal, crossbite or
scissor bites.The transverse assessment also
provides information about the width of the dental arch
and the position of the teeth on the alveolar ridge
44. Expansions in the cases where the posterior teeth
are tilted lingually/palatally tend to be stable, as the
expansion is mainly by tilting the teeth buccally.
Arch expansion is indicated for cases with
unilateral crossbite, to eliminate displacement as
well as the “V”-shaped arch form as in the thumb-
sucker .
45. The vertical analysis involves assessing the overbite
condition, which can be deep, open or incomplete.
Vertical assessment especially in the deep bite
situation, is much more accurate when using the study
cast than by clinical examination, as it is possible to
view the intercuspation from the posterior aspect of
the study casts . In addition to the study models, the
vertical dimension also needs the appropriate
radiographs (e.g. lateral cephalometric radiograph) to
make a sensible diagnosis.
46. The use of articulators
To aid diagnosis and treatment planning of
orthodontics several authors have advocated the use
of articulated study casts .According to Proffit and
Ackerman, the two main reasons to mount the study
casts are:
(1) to record and document any discrepancy
between the occlusal relations at the initial tooth
contact (centric relation) as well as the relations at
the patient’s habitual occlusion (centric occlusion),
47. and (2) to record the lateral and excursive paths of
the mandible. A recent study reported that routine
articulation of study casts for all orthodontic patients
is not advocated and will not affect the treatment
planning decisions compared with hand-held study
casts .Another use of articulators is for planning of
combined surgical orthodontics cases.
48. Model (analysis) surgery—for
combined surgical orthodontic cases
The study casts are very useful in dealing with
various aspects of orthognathic and distraction
osteogenesis . Arnett and McLaughlin recommended
that three areas of model analysis need to be
accomplished:
(1) indication for orthodontic extraction,
(2) orthodontic stability, and
(3) surgical decisions.
49. Furthermore, presurgical study casts are needed for
model planning and interocclusal splint fabrication
. The object of model planning is to determine the
intended occlusion and archform, and to decide
the exact amount and direction of movement of
the arches or segments there of. Both must be
undertaken at the same time as the photographic,
cephalometric, and computer simulation studies .
Surgical splint
50. Other information—on soft and hard
tissues
Important information about the soft and hard tissues can be
gathered from the study casts, including: gingival contour,
gingival recession, crown height, bony exostosis, unerupted
teeth (possibly shown as bulging areas), and areas of thin
cortical plate where the root outline can be visualized. From
the frontal view, the apparent sizes of teeth should become
progressively smaller from the midline distally; the
approximate golden ratio being 0.618 38. Thus, starting at the
midline, this geometric formula of proportionality predicts that
the width for each of the anterior teeth should be around 60%
of the apparent width of the tooth immediately mesial to it.
51. The palatal height of the upper arch is measured
along a virtual vertical line perpendicular to the
midpalatal raphe. A high palatal vault is a principal
feature of narrowing of the maxillary alveolar
process, which often occurs in patients who are
chronic mouth-breathers or digit suckers . On the
other hand, the presence of bony exostosis can
hinder the treatment and retention with removable
appliances.
52. Limitations of study casts
It is not possible to assess structures that are located
in the bone such as unerupted teeth with study casts.
As a general rule, if a permanent tooth on one side
erupts but its counterpart on the other fails to do so
within 6 months, an X-ray should be taken to
investigate the cause of the problem . Furthermore, it
does not provide information about the extraoral soft
tissue. Therefore, a
well-treated orthodontic case evidenced on study
casts
may not necessarily produce an esthetic smile .
53. The smile line and lip prominence are very
important, as both features will affect orthodontic
treatment modalities/ options. Certain features of
the smile are crucial for orthodontics diagnosis and
treatment planning. The transverse characteristics
of a smile depend on: (1) buccal corridor width, (2)
archforms, (3) the transverse cant of the maxillary
occlusal plane. The vertical characteristics of a
smile depend on: (1) incisor exposure and (2)
gingival display, both of which are not normally
obtainable from study casts.
54. e-Models
As we move into the 21st century there have been many
advances in dentistry, particularly with respect to digital
imaging. Digital study models can be produced by computed
tomographic scanning of a patient’s dental impression or dental
cast .This process requires silicone or polyether impressions to
be taken in the orthodontic office. Instead of being poured by
the orthodontist, impressions are shipped overnight to one of
the companies offering digital models.
Direct impression
scanning with a R700
Put the impression onto
the scanner plate: the 3D
model is just one click
away.
55. A traditional plaster model is then fabricated and, using
computer aided design and manufacturing (CAD/CAM)
technology, it is transformed into a digital, 3D image of the
dentition. Within a few days, a downloadable electronic file is
available from the Internet. Once downloaded, software
enables the digital models to be viewed and manipulated .
56. A 3D study model captured by laser scanning. The density of the meshes should be high
enough to reveal accurate occlusal morphology. Time of data acquisition is long, but the
accuracy of the final output is superior to other techniques.
57. This technique has been used for the diagnosis,
treatment planning, and fabrication of orthodontic
appliance such as the Invisalign (Align Technology,
Santa Clara, California, US), which has also been
approved by the Dental Council of Hong Kong as a
means for orthodontic recording.
58. (a) The penta-view of
OrthoCAD. The operator can
browse and view the models
separately and together from
any direction and in any
desired magnification on
screen. (b) Lingual aspects of
the upper and lower teeth can
be clearly seen and assessed
using OrthoCAD™
manipulation tools.
59. (a) The Occlusogram illustrates the amount of inter-occlusal contacts using color-
coded scales. (b) Overbite and overjet can be assessed accurately by splitting the
model along the mid-sagittal plane. (c) In addition to midline analysis, splitting can be
performed at any point and in any angle. (d) Measuring mesio-distal widths of teeth.
(e) Space analysis. (f) Three measurements of arch widths in the lower dentition.
These are just a few of the available diagnostic tools with OrthoCAD™ software.
60. The first step in OrthoCAD™ virtual set-up is to choose your preferred brackets, bands and wires from the
available straight wire systems listed. Secondly, incisors need to be positioned, as well as the molars (if
required). In the third and fourth steps, the orthodontist should slide maxillary and mandibular teeth into their
proper positions or correct the positions of the brackets themselves to achieve better inter- and intra-arch
relationships. Extractions can be simulated at this stage and the resultant space can be manipulated manually or
automatically. In the fifth step, the sagittal inter-arch relationships should be double-checked, followed by
evaluating the transverse relationships in step 6. Finally, molar position and jaw closure are adjusted to make
61. (a) Initial treatment planning with patients’ photographs and radiographs are sent to Invisalign® laboratories. (b)
Impressions are converted into positives (plaster models) and checked for quality. (c) In the laboratory, models are
first coated with protective shells, and encased in a mixture of resin and a hardener. (d) After chemical setting,
they become blocks of hardened resin with many plaster models inside. Each tray is placed in a destructive
scanning machine. (e) Each 3D model is constructed from about 300 2D scans. Graphic designers cut out each
tooth and save it as a separate geometric unit. (f) Once the teeth are separated and re-assembled back into the
arches, the designers create a final set-up of what the patient’s teeth will look like when the treatment is
completed. (g) For each stereolithographic constructed model (which represents a treatment stage), a clear
Invisalign® aligner is created by heat. (h) These aligners are trimmed, polished, cleaned and finally sent to the
prescribing orthodontist.
62. Advantages include reduction in space needed to store the
models, easy retrieval and transmission. In addition, they will
not be affected by dust and scratches anymore. Measurement
on the dental cast (such as space analysis) can be carried out
on the digital model without the cumbersome use of caliper .
(e) Space analysis. (f) Three measurements of arch widths in the lower dentition.
63. The digitized models can be viewed from any angle and also opened to
allow upper and lower models to be viewed separately. They can also
be turned back into genuine set of study models if needed .
(a) The Occlusogram illustrates the
amount of inter-occlusal contacts
using color-coded scales. (b)
Overbite and overjet can be
assessed accurately by splitting the
model along the mid-sagittal plane.
(c) In addition to midline analysis,
splitting can be performed at any
point and in any angle. (d)
Measuring mesio-distal widths of
teeth. (e) Space analysis. (f) Three
measurements of arch widths in the
lower dentition. These are just a few
of the available diagnostic tools with
OrthoCAD™ software.
64. Another advantage is the possibility of viewing digital
models at multiple locations from any office computer
linked to the practice’s central server, allowing
patients to be treated at multiple sites with easy
access to their records. Furthermore, digital models
are also an excellent presentation and patient
education tool .Thus, the digital models available
today offer seamless integration into most of
computerized practice management and imaging
systems and are part of the totally digital orthodontic
office .
65. For OrthoCAD (Cadent Inc., New Jersey, US),
alginate impressions of the dentitions with bite
registration are required for construction of 3D digital
study models, which are then downloaded manually
or automatically from the Internet using a utility
called OrthoCAD Downloader. One feature of Ortho-
CAD facilitates viewing of interocclusal contacts,
which cannot be easily done in physical models.
Another feature, OrthoCAD Bracket Placement
System enables positioning brackets according to
orthodontists’ planned positions in virtual treatment.
66. The other computerized model system is called e
models (GeoDigm Corporation, US). It features a
cross-sectioning tool that can slice the digital models
in any vertical or horizontal plane to check
symmetry, overjet, and overbite and to help measure
any location. There is a Color Bite Mapping feature
that is a visual representation of occlusal
relationships. Eplan (GeoDigm Corporation, US) is
the other useful feature of this e-model’s software.
The latter feature enables the clinician to simulate
any desired treatment option by using a virtual
diagnostic setup .
67. There are some potential limitations about digital
models, however. First, one must learn to analyze
study casts on a computer screen. It is possible to
view the casts from a myriad of angles, but
comfortable manipulation takes some practice.
Second, large practices must ensure plenty of
available computer memory. Third, to date it is not
possible to relate the casts to the hinge axis. Fourth, it
cannot be placed side by side to the teeth for
comparison.
69. The AnatoModel is a 3D digital study model created
directly from the CBCT scan data. Eliminating the need
for impressions avoids patient discomfort and saves the
orthodontist valuable chairtime, staff time, and materials.
The AnatoModel is of higher diagnostic value than other
digital models because it includes not only the tooth
crowns, but also roots, impactions, developing teeth,
and alveolar bone .Essentially, it is a model of the
patient’s complete dental anatomy.
AnatoModel* with transparent alveolar
bone, allowing visualization of roots
and developing teeth attached to
plaster-like virtual bases. (All images
generated with InVivoDental 3D
software.)
70. This 3D virtual modeling involves segmenting the
scan data into individual anatomical structures,
allowing the data to be manipulated in ways that are
not possible with raw Digital Imaging and
Communications in Medicine (DICOM) data. For
example, each dental arch can be separated from the
rest of the scan data and viewed from an occlusal
perspective, even if the scan was taken with the
patient in full occlusion .
AnatoModels created from scans with teeth in full occlusion. A. Isolation of
mandibular arch for occlusal view. B. Virtual removal of alveolar bone to isolate
71. Moreover, alveolar bone can be virtually removed to
visualize the teeth independently. This is especially
useful in mixed-dentition patients and in cases involving
impactions. Because the modeled teeth can be moved
individually to the desired end point locations and
orientations, the segmentation process facilitates virtual
setups and dynamic treatment simulation. The skeletal
anatomy can also be segmented and manipulated to
create 3D virtual treatment plans for orthognathic
surgery.
Virtual removal of alveolar bone to isolate teeth.
72. The resulting orthodontic and orthognathic treatment
simulation, involving the patient’s entire dental
anatomy,provides the foundation for the next generation of
CBCT technology: “dynamic CBCT”. As the technology
develops, the CBCT-based orthodontic treatment plan will be
integrated into the design of such therapeutic devices as
indirect-bonding appliances and orthognathic surgical guides.
AnatoModel and dynamic cone-beam computed tomography (CBCT)
orthodontic treatment simulation involving patient’s complete dental anatomy.
73. The introduction of digital models has provided the
orthodontist with a viable alternative to plaster
models with the added advantages of electronic
storage of data, minimal storage space required,
simple and accurate cataloguing and a rapid
transmission of records for consultation .
Digital model scanned with the laser scanner of the
firma 3 Shape
74. In Alexandru S. et al study they used digital models
generated by scanning of plaster casts into the computer
using 3D optical scanners. For some studies they used the
laser scanner of the firma 3Shape A/S from Copenhagen,
Denmark
Digital model scanned with the laser scanner of the
firma 3 Shape
75. Digital model scanned with the Activity 101 Scanner
For theire patients they used the optical 3D-Scanner Activity
101 from the Firma Smart Optics Sensorentechnik GmbH,
Germany.
76. The measurements on the 3D models were performed using the
OnyxCeph3TM software developed by the firma Image
Instruments GmbH, Germany.
Digital model analyzed with the OnyxCeph3TM
77. In their studies, like in many others from the recent
orthodontic literature about digital models, they found
that the measurements of dental dimensions by the
software package were very precise, and this is
probably the truth at almost all quantitative
orthodontic software.
78. Study casts provide valuable information for
orthodontic diagnosis and treatment planning.
Full utilization of such information requires
special attention and techniques. They are
important medico-legal documents that should be
obtained before commencement of every
orthodontic treatment. It is possible to be alleged
negligent for not having starting and finishing
study models.
Conclusions